Bioactivity and mechanical properties of scaffolds based on calcium aluminate and bioactive glass

Scaffolds were developed from mixtures of calcium aluminate (CA) and a bioactive glass (BG) and the effect of glass content on the mechanical strength and bioactivity of scaffolds was studied. Three different mixtures were tested: 95CA-5BG, 92.5CA-7.5BG and 90AC-10BG wt.%. Also, for comparison purpo...

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Published inInternational journal of materials research Vol. 110; no. 4; pp. 343 - 350
Main Authors García-Álvarez, G., Escobedo-Bocardo, J. C., Cortés-Hernández, D. A., Almanza-Robles, J. M.
Format Journal Article
LanguageEnglish
Published Stuttgart De Gruyter 01.04.2019
Carl Hanser Verlag
Subjects
Aluminous cements
Antibiotics
Beads
Bioactive ceramics
Biocompatibility
Bioglass
Biological activity
Biomedical materials
Body fluids
Calcium aluminate
Compressive strength
Drug delivery systems
In vitro methods and tests
Mechanical properties
Pastes
Polymethyl methacrylate
Scaffolds
Submerging
Surgical implants
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Summary:Scaffolds were developed from mixtures of calcium aluminate (CA) and a bioactive glass (BG) and the effect of glass content on the mechanical strength and bioactivity of scaffolds was studied. Three different mixtures were tested: 95CA-5BG, 92.5CA-7.5BG and 90AC-10BG wt.%. Also, for comparison purposes, pure CA was used. In order to obtain the calcium aluminate cements (CAC), mixtures were hydrated using a water/mixture ratio by weight (w/c) of 0.4 and, with the resulting pastes, scaffolds were made by the lost-spheres method using PMMA beads. These materials showed interconnected pores (215 μm average diameter). Obtained scaffolds were loaded with antibiotic (gentamicin sulfate) and its release kinetics was studied. The evaluation of the in-vitro bioactivity was carried out by immersing scaffolds in a simulated body fluid (SBF) for 1, 7, 14 or 21 days at 36.5 °C. Compressive strength was evaluated before and after each immersion period. In all cases the formation of a Ca,P-rich compound on the surface of the scaffolds was detected after immersion in SBF. The amount of the bioactive compound formed as well as compressive strength increased as the amount of bioglass was increased. A controlled antibiotic release in SBF, with diffusion-controlled kinetics, was observed. In addition, scaffolds were not hemolytic. According to the results obtained, these materials are promising candidates for biomedical applications as drug delivery systems.
ISSN:1862-5282
2195-8556
DOI:10.3139/146.111700